Technical Field
Background Art
Summary of Invention
[0004] The present disclosure provides a fusion splicing apparatus according to claim 1.
Brief Description of Drawings
[0005]
[FIG. 1] FIG. 1 is a perspective view illustrating an external appearance of a fusion
splicing apparatus according to one embodiment and illustrates an external appearance
in a state in which a windproof cover is closed.
[FIG. 2] FIG. 2 is a perspective view illustrating an external appearance of the fusion
splicing apparatus according to one embodiment and illustrates an external appearance
in a state in which the windproof cover is opened and an internal structure of the
fusion splicing apparatus can be seen.
[FIG. 3] FIG. 3 is a functional block diagram illustrating a configuration of an internal
system provided in the fusion splicing apparatus.
[FIG. 4] FIG. 4 is a block diagram illustrating an example of a hardware configuration
of a fusion control unit.
[FIG. 5] FIG. 5 is a flowchart illustrating an operation of the fusion control unit.
[FIG. 6] FIG. 6 is a flowchart illustrating the operation of the fusion control unit.
Description of Embodiments
[Problems to be Solved by the Disclosure]
[0006] A fusion splicing apparatus to fusion splice optical fibers is compactly configured
so that it is easily carried for ease of use at construction sites or the like. Such
a fusion splicing apparatus is generally expensive because a structure thereof is
complicated and requires a high degree of precision. There is a problem that the fusion
splicing apparatus may be stolen at a construction site or carried away without being
returned as it is after being lent. Thus, it is desired that the fusion splicing apparatus
have a function of setting a usable period at the start of use (or at the start of
lending) and disabling (locking) the fusion splicing when the usable period has elapsed.
In that case, the fusion splicing apparatus needs to include a real-time clock (RTC)
that keeps counting a date and time regardless of power on/off of the fusion splicing
apparatus to accurately determine whether or not the usable period has elapsed.
[0007] If an abnormality occurs in the RTC and an accurate date and time cannot be output,
determining whether or not the usable period has elapsed is impossible, and it becomes
difficult to lock the fusion splicing function. It is also conceivable to take advantage
of this and intentionally break the RTC of the fusion splicing apparatus that has
been stolen or the like to make it impossible to lock the fusion splicing function.
Further, it is also conceivable to lock the fusion splicing function when an abnormality
of the RTC is detected, but if it is merely due to a failure of the RTC, there is
a likelihood that fusion splicing work cannot be performed within a construction period
and a user suffers great damage.
[Advantageous effects of invention]
[0008] According to the present disclosure, the fusion splicing function can be locked after
a period close to the usable period even when an abnormality occurs in the RTC.
[Explanation of Embodiments of the Disclosure]
[0009] First, contents of the embodiments of the present invention will be listed and described.
A fusion splicing apparatus according to one embodiment includes a fusion splicing
unit configured to fusion splice optical fibers by electric discharges, a clock unit
configured to output a current date and time, and a fusion control unit configured
to control an operation of the fusion splicing unit and stop the operation of the
fusion splicing unit when a remaining period of use known on the basis of the current
date and time output from the clock unit and a usable period input from the outside
in advance is zero or less. The fusion control unit records information on the number
of times of electric discharge per unit period when the clock unit is normal and determines
the remaining period of use assuming that the unit period has elapsed when the number
of times of electric discharge has reached the number of times of electric discharge
per unit period in a case in which an abnormality of the clock unit is detected.
[0010] In the fusion splicing apparatus, when the remaining period of use known from the
current date and time and the usable period is zero or less, the fusion control unit
stops the operation of the fusion splicing unit. Thereby, it is possible to realize
a function of setting a usable period, for example, at the start of use (or at the
start of lending) and disabling (locking) the fusion splicing when the usable period
has elapsed. Further, the fusion control unit records information on the number of
times of electric discharge per unit period when the clock unit is normal. When an
abnormality of the clock unit is detected, the fusion control unit determines the
remaining period of use assuming that the unit period has elapsed when the number
of times of electric discharge has reached the number of times of electric discharge
per unit period. Thereby, the fusion splicing function can be locked after a period
close to the usable period even when an abnormality occurs in the clock unit.
[0011] In the above-described fusion splicing apparatus, the unit period may be N days (N
is an integer of 1 or more). When construction work including the fusion splicing
of optical fibers is performed, the work is often carried out in a daily cycle, such
as working during daytime and resting at night (or vice versa). Thus, when the above-described
unit period is set in units of days such as N days, the number of times of electric
discharge per unit period is stable and the remaining period of use can be determined
more accurately.
[0012] In the above-described fusion splicing apparatus, the fusion control unit may determine
the clock unit as abnormal when a signal on a date and time is not output from the
clock unit. Thereby, an abnormality of the clock unit can be appropriately determined.
[0013] In the above-described fusion splicing apparatus, the fusion control unit may determine
the clock unit as abnormal when a current date and time output from the clock unit
is earlier than a date and time stored in advance. Thereby, an abnormality of the
clock unit can be appropriately determined.
[0014] In the above fusion splicing apparatus, the fusion control unit may determine the
remaining period of use assuming that the unit period has elapsed when the number
of times of electric discharge has reached a moving average value of the number of
times of electric discharge per unit period that has been recorded when the clock
unit is normal in a case in which an abnormality of the clock unit is detected. Thereby,
even when the number of times of electric discharge per unit period changes for each
unit period, the remaining period of use can be determined more accurately.
[0015] [Detailed description of Embodiments of the Present Disclosure] Specific examples
of a fusion splicing apparatus according to the embodiments of the present disclosure
will be described below with reference to the drawings. The present invention is not
limited to these examples but is defined by the scope of the claims, and is intended
to include meanings equivalent to the claims and all modifications within the scope.
In the following description, the same elements will be denoted by the same reference
signs in the description of the drawings, and duplicate description thereof will be
omitted.
[0016] FIGS. 1 and 2 are perspective views illustrating an external appearance of a fusion
splicing apparatus 10 according to the present embodiment. FIG. 1 illustrates an external
appearance in a state in which a windproof cover is closed, and FIG. 2 illustrates
an external appearance in a state in which the windproof cover is opened and an internal
structure of the fusion splicing apparatus 10 can be seen. The fusion splicing apparatus
10 is an apparatus for fusion splicing optical fibers to each other by electric discharges
and includes a box-shaped housing 2 as illustrated in FIGS. 1 and 2. A fusion splicing
unit 3 for fusing the optical fibers to each other and a heater 4 are provided on
an upper portion of the housing 2. The heater 4 heats and contracts a fiber reinforcing
sleeve covering a fused portion of the optical fibers. The fusion splicing apparatus
10 further includes a monitor 5, a windproof cover 6, a power switch 7, and a splicing
start switch 8. The monitor 5 displays a fusion connection state of the optical fibers
captured by a camera (not illustrated) disposed inside the housing 2. The windproof
cover 6 prevents wind from entering the fusion splicing unit 3. The power switch 7
is a push button for switching power of the fusion splicing apparatus 10 on/off according
to an operation of a user. The splicing start switch 8 is a push button for starting
an operation for fusing the optical fibers to each other according to an operation
of the user.
[0017] As illustrated in FIG. 2, the fusion splicing unit 3 includes a pair of fiber positioning
parts 3a, a pair of discharging electrodes 3b, and a holder placing part on which
a pair of optical fiber holders 3c can be placed. Optical fibers to be fused are held
and fixed in the optical fiber holders 3c, and the optical fiber holders are placed
on and fixed to the holder placing part. The fiber positioning parts 3a are disposed
between the optical fiber holders 3c and position distal end portions of the optical
fibers held in the optical fiber holders 3c. The discharging electrodes 3b are disposed
between the fiber positioning parts 3a and fuse the distal ends of the optical fibers
together by an arc discharge. In the fusion splicing apparatus 10, conditions of various
types such as fiber positioning processing by the fiber positioning parts 3a and the
arc discharging by the discharging electrodes 3b are controlled by operation software
stored in a memory or the like of the fusion splicing apparatus 10.
[0018] FIG. 3 is a functional block diagram illustrating a configuration of an internal
system provided in the fusion splicing apparatus 10. As illustrated in FIG. 3, the
fusion splicing apparatus 10 includes a clock unit 11 and a fusion control unit 12
in addition to the fusion splicing unit 3 described above. The clock unit 11 is a
real-time clock (also called RTC or a hardware clock) that outputs a current date
and time and receives a backup of power from a battery to constantly keep counting
the current date and time regardless of a power supply state (on/off) of the fusion
splicing apparatus 10. The clock unit 11 may be configured by, for example, an IC
and provided as an independent semiconductor chip mounted on a circuit board. Typically,
the clock unit 11 outputs information of "year," "month," "day," "hour," "minute,"
and "second" as an electric signal.
[0019] The fusion control unit 12 is configured to include a basic control unit 13, a clock
abnormality detection unit 14, a remaining period of use calculation unit 15, and
a remaining period of use estimation unit 16. The basic control unit 13 controls an
operation of the fusion splicing unit 3. That is, the basic control unit 13 receives
an operation of the splicing start switch 8 by the user and controls a contact operation
and an arc discharge between the distal ends of the optical fibers in the fusion splicing
unit 3. The control of arc discharge includes control of discharge voltage and control
of discharge timing. The clock abnormality detection unit 14 receives an input of
a signal from the clock unit 11 and detects an abnormality of the clock unit 11. From
the normal clock unit 11, a signal on the current date and time is constantly output
during operation. When a signal on the date and time is not output from the clock
unit 11, the clock abnormality detection unit 14 determines the clock unit 11 as abnormal.
Alternatively, even when a signal on the date and time is output from the clock unit
11, the date and time may be obviously incorrect. When the date and time output from
the clock unit 11 is earlier than a date and time stored in advance (for example,
a date and time set at the time of product shipment or a date and time when power
was last turned off), the clock abnormality detection unit 14 may also determine the
clock unit 11 as abnormal. The abnormality determination methods of the clock unit
11 described above are examples, and various other methods that enable an abnormality
of the clock unit 11 to be detected can be applied.
[0020] The remaining period of use calculation unit 15 calculates a remaining period of
use on the basis of the current date and time output from the clock unit 11 and a
usable period input from the outside in advance. The "usable period" is a period preset
by the user, a lender, or the like, and the basic control unit 13 stops control of
the fusion splicing unit 3 and the fusion splicing unit 3 becomes inoperable (locked
state) when the usable period has timed out. In this case, even if the user operates
the splicing start switch 8, fusion of the optical fibers is not performed. Since
such a function extremely limits the original function of the fusion splicing apparatus
10 after it is stolen or carried away, an effect of preventing the fusion splicing
apparatus 10 from being stolen or carried away itself is expected. When the remaining
period of use is zero or less, the remaining period of use calculation unit 15 outputs
a signal for stopping the operation of the fusion splicing unit 3 to the basic control
unit 13. Alternatively, the basic control unit 13 may stop the operation of the fusion
splicing unit 3 when information on the remaining period of use is provided from the
remaining period of use calculation unit 15 to the basic control unit 13 and the remaining
period of use is zero or less. The remaining period of use may be set, for example,
in units of days. The remaining period of use calculation unit 15 records the calculated
remaining period of use in a non-volatile storage means (a ROM or the like). A determination
as to whether or not the remaining period of use is zero or less is performed at least
once each time the power switch 7 is operated and power supply to the fusion splicing
apparatus 10 enters an ON state.
[0021] The remaining period of use estimation unit 16 acquires the number of times (the
number of times of electric discharge) fusion splicing has been performed by the arc
discharge. The number of times of electric discharge is counted by the remaining period
of use estimation unit 16 on the basis of an input from the splicing start switch
8 by the user or a signal from the basic control unit 13. The remaining period of
use estimation unit 16 further receives an output signal from the clock abnormality
detection unit 14, and when the clock unit 11 is normal, records information on the
number of times of electric discharge per unit period (for example, the number of
times of electric discharge per unit period itself, or its moving average value) in
a non-volatile storage means (a ROM or the like). The unit period may be, for example,
N days (N is an integer of 1 or more) and typically one day. The moving average value
is a moving average value over a recent plurality of unit periods and is a moving
average value of the past M days (M is an integer of 2 or more) when the unit period
is one day. The value of M may be, for example, 30. At the time of product shipment,
an initial value of the number of times of electric discharge per unit period is recorded
in advance.
[0022] When the clock abnormality detection unit 14 detects an abnormality in the clock
unit 11, the remaining period of use calculation unit 15 cannot calculate the remaining
period of use. Thus, the remaining period of use estimation unit 16 estimates the
remaining period of use as follows. That is, when the clock abnormality detection
unit 14 detects an abnormality in the clock unit 11, the remaining period of use estimation
unit 16 refers to the information on the number of times of electric discharge per
unit period recorded in the storage means while acquiring the number of times of electric
discharge. Then, the remaining period of use estimation unit 16 calculates the remaining
period of use assuming that the unit period has elapsed when the number of times of
electric discharge has reached the recorded number of times of electric discharge
per unit period (or its moving average value). When the remaining period of use is
zero or less, the remaining period of use estimation unit 16 outputs a signal for
stopping the operation of the fusion splicing unit 3 to the basic control unit 13.
Alternatively, when the information on the remaining period of use is provided from
the remaining period of use estimation unit 16 to the basic control unit 13 and the
remaining period of use is zero or less, the basic control unit 13 may stop the operation
of the fusion splicing unit 3. A determination as to whether or not the remaining
period of use is zero or less is performed at least once each time the power switch
7 is operated and power supply to the fusion splicing apparatus 10 enters an ON state.
[0023] FIG. 4 is a block diagram illustrating an example of a hardware configuration of
the fusion control unit 12. As illustrated in FIG. 4, the fusion control unit 12 may
be configured as a computer including a CPU 12a, a RAM 12b, and a ROM 12c. The fusion
control unit 12 can realize each function of the fusion control unit 12 by performing
reading and writing of data with respect to the RAM 12b and the ROM 12c under control
of the CPU 12a while executing reading of a program stored in the ROM 12c in advance.
An operating state of the fusion control unit 12 is always displayed on the monitor
5 during the operation of the fusion splicing apparatus 10. The fusion control unit
12 is electrically connected to the splicing start switch 8 and receives an electric
signal from the splicing start switch 8. The fusion control unit 12 further includes
an input device 12d for inputting the usable period from the outside. The input device
12d may be configured by, for example, a wired communication port such as USB (Universal
Serial Bus) or a wireless communication circuit corresponding to a wireless standard
such as IEEE 802.11.
[0024] FIGS. 5 and 6 are flowcharts illustrating an operation of the fusion control unit
12. When the power switch 7 is operated and power supply to the fusion splicing apparatus
10 enters an ON state, first, the clock abnormality detection unit 14 of the fusion
control unit 12 determines whether or not an abnormality has occurred in the clock
unit 11 (Step S1). When the clock unit 11 is normal (step S1: NO), the remaining period
of use calculation unit 15 reads a set usable period from the storage means such as
the ROM and receives an input of a current date and time from the clock unit 11. Then,
the remaining period of use calculation unit 15 calculates a remaining period of use
from the usable period and the current date and time and determines whether or not
the remaining period of use is zero or less (step S2). When the remaining period of
use is zero or less (step S2: YES), the basic control unit 13 stops an operation of
the fusion splicing unit 3 (step S3). When the remaining period of use is greater
than 0 (step S2: NO), the basic control unit 13 allows the operation of the fusion
splicing unit 3. Then, the remaining period of use is recorded in the storage means
such as the ROM (step S4).
[0025] Next, the remaining period of use estimation unit 16 determines whether or not a
unit period has elapsed from a first date and time (date and time when a first fusion
processing has been performed after a previous unit period has elapsed) recorded in
the storage means such as the ROM (step S5). When the unit period has elapsed from
the first date and time (step S5: YES), the remaining period of use estimation unit
16 updates information on the number of times of electric discharge per unit period
recorded in the storage means on the basis of the cumulative number of times of electric
discharge within the unit period at that time (step S6). For example, when the information
on the number of times of electric discharge per unit period is a moving average value,
the remaining period of use estimation unit 16 counts the cumulative number of times
of electric discharge as a latest number of times of electric discharge per unit period
and updates the moving average value. Thereafter, the cumulative number of times of
electric discharge is initialized (step S7). When the unit period has not elapsed
from the first date and time (step S5: NO), the above-described steps S6 and S7 are
not performed, and the processing proceeds to a next step.
[0026] When the user operates the splicing start switch 8 and fusion processing by an arc
discharge is performed (step S8), the remaining period of use estimation unit 16 checks
the cumulative number of times of electric discharge within the unit period (step
S9). When the cumulative number of times of electric discharge within the unit period
is zero (step S9: YES), the remaining period of use estimation unit 16 records a date
and time at that time in the storage means such as the ROM as the first date and time
(step S10). After step S9, or when the cumulative number of times of electric discharge
within the unit period is one or more (step S9: NO), the remaining period of use estimation
unit 16 adds 1 to the cumulative number of times of electric discharge in the unit
period (step S11). Thereafter, the processing returns to step S8 again. Such steps
S8 to S11 are repeatedly performed until the power switch 7 is operated and power
supply to the fusion splicing apparatus 10 enters an OFF state.
[0027] On the other hand, when the clock unit 11 is abnormal in step S1 (step S1: YES),
the remaining period of use is read from the storage means such as a ROM by the remaining
period of use estimation unit 16, and it is determined whether or not the remaining
period of use is zero or less (step S12). When the remaining period of use is zero
or less (step S12: YES), the basic control unit 13 stops the operation of the fusion
splicing unit 3 (step S13). When the remaining period of use is greater than zero
(step S12: NO), the basic control unit 13 allows the operation of the fusion splicing
unit 3.
[0028] When the user operates the splicing start switch 8 and fusion processing by the arc
discharge is performed (step S14), the remaining period of use estimation unit 16
checks the cumulative number of times of electric discharge within the unit period
(step S15). When the cumulative number of times of electric discharge within the unit
period has reached the number of times of electric discharge per unit period (or its
moving average value) recorded in the storage means such as the ROM (step S15: YES),
the remaining period of use estimation unit 16 records a new remaining period of use
obtained by subtracting 1 from the remaining period of use in the storage means such
as the ROM (step S16) and initializes the cumulative number of times of electric discharge
within the unit period (step S17). When the cumulative number of times of electric
discharge within the unit period has not reached the number of times of electric discharge
per unit period (or its moving average value) recorded in the storage means such as
the ROM (step S15: NO), the above-described steps S16 and S17 are not performed. Thereafter,
the processing returns to step S14 again. Such steps S14 to S17 are repeatedly performed
until the power switch 7 is operated and power supply to the fusion splicing apparatus
10 enters an OFF state.
[0029] Effects that can be obtained by the fusion splicing apparatus 10 according to the
present embodiment described above will be described. In the fusion splicing apparatus
10, when the remaining period of use known from the current date and time and the
usable period is zero or less, the fusion control unit 12 stops the operation of the
fusion splicing unit 3. Thereby, it is possible to realize a function of setting a
usable period, for example, at the start of use (or at the start of lending) and disabling
(locking) the fusion splicing when the usable period has elapsed. Further, the fusion
control unit 12 records information on the number of times of electric discharge per
unit period when the clock unit 11 is normal. Then, when an abnormality of the clock
unit 11 is detected, the fusion control unit 12 determines the remaining period of
use assuming that the unit period has elapsed when the number of times of electric
discharge has reached the number of times of electric discharge per unit period. Thereby,
the fusion splicing function can be locked after a period close to the usable period
even when an abnormality occurs in the clock unit 11.
[0030] In the method of the present embodiment, although it is difficult to perform lock
processing that accurately corresponds to the usable period, lock processing can be
performed with an approximate period that is not so different from the usable period
(for example, an error of several days when the unit period is one day). In order
to prevent the fusion splicing apparatus from being stolen or carried away, sufficient
effects can be obtained even with such a rough period setting. This is because no
value can be found in stealing or carrying away the fusion splicing apparatus 10 if
it is generally recognized that the fusion splicing apparatus 10 cannot be used in
the near future even if it is illegally acquired. On the other hand, when the clock
unit 11 becomes abnormal due to a mere failure, if the fusion splicing function is
locked before the set usable period has elapsed, this may affect a construction period
of the user. Therefore, a grace period (for example, a grace period of several days
when the unit period is one day) may be provided between the time when the remaining
period of use estimated from the number of times of electric discharge is zero or
less and the time when the operation of the fusion splicing unit 3 is stopped.
[0031] As in the present embodiment, the unit period may be N days (N is an integer of 1
or more). When construction work including the fusion splicing of optical fibers is
performed, the work is often carried out for a day cycle, such as working during daytime
and resting at night (or vice versa). Thus, when the above-described unit period is
set in units of days such as N days, the number of times of electric discharge per
unit period is stable and the remaining period of use can be determined more accurately.
[0032] As in the present embodiment, the fusion control unit 12 may determine the clock
unit 11 as abnormal when a signal on a date and time is not output from the clock
unit 11. Alternatively, when a current date and time output from the clock unit 11
is earlier than the date and time stored in advance, the fusion control unit 12 may
determine the clock unit 11 as abnormal. According to one or both of these, an abnormality
in the clock unit 11 can be appropriately determined.
[0033] As in the present embodiment, when an abnormality in the clock unit 11 is detected,
the fusion control unit 12 may determine the remaining period of use assuming that
the unit period has elapsed when the number of times of electric discharge has reached
the moving average value of the number of times of electric discharge per unit period
that has been recorded when the clock unit 11 is normal. Thereby, even when the number
of times of electric discharge per unit period changes for each unit period, the remaining
period of use can be determined more accurately.
[0034] Although the fusion splicing apparatus according to the present embodiment has been
described above, the fusion splicing apparatus according to the present invention
is not limited to the above-described embodiment and various modifications can be
applied thereto.
Reference Signs List
[0035]
2 Housing
3 Fusion splicing unit
3a Fiber positioning part
3b Discharging electrode
3c Optical fiber holder
4 Heater
5 Monitor
6 Windproof cover
7 Power switch
8 Splicing start switch
10 Fusion splicing apparatus
11 Clock unit
12 Fusion control unit
12a CPU
12b RAM
12c ROM
12d Input device
13 Basic control unit
14 Clock abnormality detection unit
15 Remaining period of use calculation unit
16 Remaining period of use estimation unit
1. A fusion splicing apparatus (10) for optical fibers comprising:
a fusion splicing unit (3) configured to fusion splice optical fibers by electric
discharges;
a clock unit (11) configured to output a current date and time; and
a fusion control unit (12) configured to control an operation of the fusion splicing
unit (3) and stop the operation of the fusion splicing unit (3) when a remaining period
of use known on the basis of the current date and time output from the clock unit
(11) and a usable period input from the outside in advance is zero or less,
wherein the fusion control unit (12) comprises a clock abnormality detection unit
(14) arranged to detect an abnormality in the clock unit (11);
wherein the fusion control unit (12) further comprises a remaining period of use calculation
unit (15) and a remaining period of use estimation unit (16), wherein the remaining
period of use calculation unit (15) is arranged to provide the remaining period of
use known on the basis of the current date and time output from the clock unit (11)
and the usable period input from the outside in advance;
wherein the remaining period of use estimation unit (16) is configured to record information
on the number of times of electric discharge per unit period when the clock unit (11)
is normal and configured to determine the remaining period of use assuming that the
unit period has elapsed when the number of times of electric discharge has reached
the number of times of electric discharge per unit period in a case in which an abnormality
of the clock unit (11) is detected.
2. The fusion splicing apparatus (10) according to claim 1, wherein the unit period is
N days (N is an integer of 1 or more).
3. The fusion splicing apparatus (10) according to claim 1 or 2, wherein the fusion control
unit (12) determines the clock unit (11) as abnormal when a signal on a date and time
is not output from the clock unit.
4. The fusion splicing apparatus (10) according to claim 1 or 2, wherein the fusion control
unit (12) determines the clock unit (11) as abnormal when a date and time output from
the clock unit (11) is earlier than a date and time stored in advance.
5. The fusion splicing apparatus (10) according to any one of claims 1 to 4, wherein
the fusion control unit (12) determines the remaining period of use assuming that
the unit period has elapsed when the number of times of electric discharge has reached
a moving average value of the number of times of electric discharge per unit period
that has been recorded when the clock unit (11) is normal in a case in which an abnormality
of the clock unit is detected.
1. Fusionsspleißvorrichtung (10) für optische Fasern, umfassend:
eine Fusionsspleißeinheit (3), die zum Fusionsspleißen von optischen Fasern durch
elektrische Entladungen konfiguriert ist;
eine Uhreinheit (11), die zum Ausgeben eines aktuellen Datums und einer aktuellen
Uhrzeit konfiguriert ist;
und
eine Fusionssteuereinheit (12), die zum Steuern eines Betriebs der Fusionsspleißeinheit
(3) und zum Anhalten des Betriebs der Fusionsspleißeinheit (3) konfiguriert ist, wenn
eine Restnutzungszeit, die auf der Basis des aktuellen Datums und der aktuellen Zeit,
die von der Uhreneinheit (11) ausgegeben werden, und einer nutzbaren Zeitspanne, die
von außen im Voraus eingegeben wird, bekannt ist, Null oder weniger ist,
wobei die Fusionssteuereinheit (12) eine Uhrabnormalität-Erfassungseinheit (14) umfasst,
die zum Erfassen einer Abnormalität der Uhreinheit (11) eingerichtet ist;
wobei die Fusionssteuereinheit (12) weiter eine Restnutzungszeit-Berechnungseinheit
(15) und eine Restnutzungszeit-Schätzeinheit (16) umfasst, wobei die Restnutzungszeit-Berechnungseinheit
(15) zum Bereitstellen der Restnutzungszeit eingerichtet ist,
die auf der Basis des aktuellen Datums und der aktuellen Zeit, die von der Uhreneinheit
(11) ausgegeben werden, und einer nutzbaren Zeitspanne, die von außen im Voraus eingegeben
wird, bekannt ist;
wobei die Restnutzungszeit-Schätzeinheit (16) zum Aufzeichnen von Informationen über
die Anzahl von elektrischen Entladungen pro Einheitsperiode konfiguriert ist, wenn
die Uhreinheit (11) normal ist, und zum Bestimmen
die Restnutzungszeit unter der Annahme,
dass die Einheitsperiode verstrichen ist, wenn die Anzahl von Malen elektrischer Entladung
die Anzahl von Malen elektrischer Entladung pro Einheitsperiode in einem Fall erreicht
hat, in dem eine Abnormalität der Uhreinheit (11) erfasst wird.
2. Fusionsspleißvorrichtung (10) nach Anspruch 1, wobei die Einheitsperiode N Tage beträgt
(N ist eine ganze Zahl von 1 oder mehr).
3. Fusionsspleißvorrichtung (10) nach Anspruch 1 oder 2, wobei die Fusionssteuereinheit
(12) die Uhreinheit (11) als abnormal bestimmt, wenn von der Uhreinheit kein Signal
über ein Datum und eine Uhrzeit ausgegeben wird.
4. Fusionsspleißvorrichtung (10) nach Anspruch 1 oder 2, wobei die Fusionssteuereinheit
(12) die Uhreinheit (11) als abnormal bestimmt, wenn eine Datums- und Zeitausgabe
von der Uhreinheit (11) früher als ein im Voraus gespeichertes Datum und eine im Voraus
gespeicherte Zeit ist.
5. Fusionsspleißvorrichtung (10) nach einem der Ansprüche 1 bis 4, wobei die Fusionssteuereinheit
(12) die Restnutzungszeit unter der Annahme bestimmt, dass die Zeitspanne abgelaufen
ist, wenn die Anzahl der elektrischen Entladungen einen gleitenden Durchschnittswert
der Anzahl der elektrischen Entladungen pro Zeitspanne erreicht hat, der aufgezeichnet
wurde, wenn die Uhrzeiteinheit (11) normal ist, in einem Fall, in dem eine Abnormalität
der Uhrzeiteinheit erfasst wird.
1. Appareil (10) d'épissage par fusion pour fibres optiques comprenant :
une unité (3) d'épissage par fusion configurée pour épisser par fusion des fibres
optiques par décharges électriques ;
une unité (11) d'horloge configurée pour délivrer en sortie une date et une heure
actuelles ; et
une unité (12) de commande de fusion configurée pour commander un fonctionnement de
l'unité (3) d'épissage par fusion et arrêter le fonctionnement de l'unité (3) d'épissage
par fusion lorsqu'une période d'utilisation restante connue sur la base de la date
et de l'heure actuelles délivrées en sortie par l'unité (11) d'horloge et d'une période
utilisable entrée depuis l'extérieur à l'avance est inférieure ou égale à zéro,
dans lequel l'unité (12) de commande de fusion comprend une unité (14) de détection
d'anomalie d'horloge agencée pour détecter une anomalie dans l'unité (11) d'horloge
;
dans lequel l'unité (12) de commande de la fusion comprend en outre une unité (15)
de calcul de période d'utilisation restante et une unité (16) d'estimation de période
d'utilisation restante, dans lequel l'unité (15) de calcul de période d'utilisation
restante est agencée de manière à fournir la période d'utilisation restante connue
sur la base de la date et de l'heure actuelles délivrées en sortie par l'unité (11)
d'horloge et d'une période utilisable entrée depuis l'extérieur à l'avance ;
dans lequel l'unité (16) d'estimation de période d'utilisation restante est configurée
pour enregistrer des informations sur le nombre de décharges électriques par période
unitaire lorsque l'unité (11) d'horloge est normale et configurée pour déterminer
la période restante d'utilisation en supposant que la période unitaire s'est écoulée
lorsque le nombre de décharges électriques a atteint le nombre de décharges électriques
par période unitaire dans un cas où une anomalie de l'unité (11) d'horloge est détectée.
2. Appareil (10) d'épissage par fusion selon la revendication 1, dans lequel la période
unitaire est de N jours (N est un entier de 1 ou plus).
3. Appareil (10) d'épissage par fusion selon la revendication 1 ou la revendication 2,
dans lequel l'unité (12) de commande de fusion détermine que l'unité (11) d'horloge
est anormale lorsqu'un signal sur une date et une heure n'est pas délivré en sortie
par l'unité d'horloge.
4. Appareil (10) d'épissage par fusion selon la revendication 1 ou la revendication 2,
dans lequel l'unité (12) de commande de fusion détermine que l'unité (11) d'horloge
est anormale lorsqu'une date et une heure délivrées en sortie par l'unité (11) d'horloge
sont antérieures à une date et une heure stockées à l'avance.
5. Appareil (10) d'épissage par fusion selon l'une quelconque des revendications 1 à
4, dans lequel l'unité (12) de commande de fusion détermine la période d'utilisation
restante en supposant que la période unitaire s'est écoulée lorsque le nombre de décharges
électriques a atteint une valeur moyenne mobile du nombre de décharges électriques
par période unitaire qui a été enregistrée lorsque l'unité (11) d'horloge est normale
dans un cas où une anomalie de l'unité d'horloge est détectée.